A bioengineered factory for T-cells

Injectable sponge-like gel enhances the quantity and quality of T-cells

Bone marrow transplants, also known as hematopoietic stem cell transplants, are life-saving treatments for aggressive diseases, such as leukemia and multiple myeloma, and infections such as HIV. The procedure entails infusion of blood stem cells from a matched donor into the patient to ‘reset’ the blood and immune system.

Immune cells develop from blood stem cells that reside in the bone marrow. In order to treat the disease and prevent the patient's body from rejecting the transplanted cells, patients undergo intensive conditioning, which involves the administration of chemotherapy and radiation. However, the conditioning regimen also significantly compromises the functioning of normal cells in the bone marrow and therefore compromises their ability to regenerate the immune system. This includes a reduced ability to generate T-cells and causes profound long-term post-transplant immune deficiency, increases the risk of opportunistic infectious diseases and immunological complications such as graft-versus-host-disease.

Now, Harvard engineers and stem cell biologists have developed an injectable sponge-like gel that enhances the production T-cells after a bone marrow transplant, increasing the quantity and diversity of these key components of the immune system. This bioengineered device can be injected under the skin at the same time as the transplant to help revive the immune system after bone marrow transplantation.

An SEM cross-section of the injectable sponge. (Image courtesy of the researchers.)

“T-cell deficiency and dysfunction is a life-threatening challenge, especially in transplant settings,” said David Scadden, the Gerald and Darlene Jordan Professor of Medicine and Co-Director of the Harvard Stem Cell Institute, and co-senior author on the paper. “Our research demonstrates a simple to administer, off-the-shelf solution that can enhance T-cell regeneration after stem cell transplantation.”

Mooney is also a Core Faculty Member of the Harvard’s Wyss Institute for Biologically Inspired Engineering.

Previous research into reinvigorating the immune system after a bone marrow transplant has focused primarily on improving the function of the thymus, the organ that is necessary for T-cell production. Mooney, Scadden and their team focused on the bone marrow, which is the home of the blood stem cells, and devised a method to expand the cells that migrate to the thymus to eventually give rise to new T-cells. These cells, known as common lymphoid progenitors, are made in the bone marrow.

“Our goal was to enhance the production of these cells, which are like the entry product to the foundry that produces T-cells, by creating a little bone marrow-like environment,” said Scadden.

Drawing upon the Mooney Lab’s pioneering research in the development of biomaterials for providing cell-instructive cues, the researchers engineered a sponge-like cell factory, with large pores that allows cells to move in and out. The sponge has two built-in proteins, one that recruits outside cells and the other to create the T-cell progenitors. The first, called bone morphogenetic protein 2, recruits local cells and encourages them to become bone cells. Once the sponge resembles vascularized bone marrow, the second protein encourages the blood stem cells living in the device to produce T-cell progenitors.

When the researchers tested the device in mice receiving a hematopoietic stem cell transplant, they found that the mice treated with the scaffold generated T-cells faster when compared with mice that did not.

“We also found that not only are we enhancing the rate at which these T cells form after transplant but we are also increasing the diversity in the types of T cells that are formed,” said Nisarg Shah, a former postdoctoral fellow and the lead author on the paper, who is now faculty member at the University of California, San Diego. “So, we are improving not only the number of T-cells but also, potentially, the breadth of pathogen recognition capabilities and protection.”

A stained section of the cryogel with alginate identified (red thread-like staining) at days 10 after transplantation. (Image courtesy of the researchers.)

The researchers also found that in mice with the implanted scaffold, the frequency of graft versus host disease, in which donor cells may attack the patient’s healthy tissues and organs, was significantly reduced.

“The prospects here are exciting,” said Bruce Blazar, Professor of Pediatrics in the Division of Blood and Marrow Transplantation at the University of Minnesota, who was not involved in this study. “A major limitation of hematopoietic stem cell transplantation is the inability of the recipient to rapidly regenerate T-cells to mount an immune response against foreign antigens. Using a biomaterial-based cryogel scaffold, Drs. Shah, Mooney and Scadden have offered a pathway to solving this obstacle by providing an implantable 3D system and key ligands for recruiting supporting cells and inducing T cell lineage fate and differentiation resulting in improved T cell recovery after transfer of mouse or human cells.”

Next, the researchers aim to scale up the research to be applicable in a clinical setting.

“The ultimate goal is to make this into a product that physicians can prescribe and use,” said Scadden.

“This is a very nice study in which the authors developed a novel gel that is very easy to administer and at the same time has the ability to enhance T cell regeneration after hematopoietic stem cell transplantation,” said Robert Langer, Professor of Chemical Engineering at MIT who was not involved in this study. “I expect with further work this could become a useful therapy for patients. “

To that end, this project received funding and strategic support from Harvard’s Blavatnik Biomedical Accelerator, which advances early-stage biomedical research toward key milestones that would validate the innovations in the eyes of prospective corporate partners or investors. Harvard Office of Technology Development is exploring a number of avenues for further development and commercialization of the technology.

This research was co-authored by Angelo S. Mao, Ting-Yu Shih, Matthew D. Kerr, Azeem Sharda, Theresa Raimondo, James C. Weaver, Vladimir D. Vrbanac, Maud Deruaz, and Andrew M. Tager. This research was supported by the National Institutes of Health, the Cancer Research Institute and the Blavatnik Biomedical Accelerator Program at Harvard University.